WO2018137423A1

WO2018137423A1 - Horizontal drive assembly of dual power source vehicle

Info

Publication number: WO2018137423A1
Application number: PCT/CN2017/115670
Authority: WO
Inventors: 余平; 杨昌祺; 李建文
Original assignee: 精进电动科技股份有限公司
Priority date: 2017-01-24
Filing date: 2017-12-12
Publication date: 2018-08-02
Also published as: US20190389299A1; EP3552856A4; JP2020506839A; EP3552856B1; EP3552856A1; JP7049346B2; CN106740024A; US11052746B2

Abstract

A horizontal drive assembly of a dual power source vehicle, comprising two power sources and an automatic transmission (10). The automatic transmission (10) is provided with a first input shaft (21) and a second input shaft (22). The two power sources are connected to the two input shafts (21, 22) respectively. A first intermediate shaft (31) is provided in parallel to the first input shaft (21). A second intermediate shaft (32) is provided in a direction coaxial with the first input shaft (21). A third intermediate shaft (33) is provided in a direction coaxial with the first intermediate shaft (31). A first gear (11) on the first input shaft (21) is in engaged transmission with a second gear (12) on the first intermediate shaft (31). A third gear (13) on the second intermediate shaft (32) is in engaged transmission with a fourth gear (14) on the second intermediate shaft (34). A fifth gear (15) on the second intermediate shaft (32) is in engaged transmission with a sixth gear (16) on the third intermediate shaft (33). The sixth gear (16) is also in engaged transmission with a seventh gear (17) on a differential (50). On one hand, the drive assembly reduces the longitudinal size and is suitable for a vehicle having a compact structure. On the other hand, the number of gears used is small and a transmission structure is simplified.

Description

Transverse dual power source vehicle drive assembly

Technical field

The present invention relates to a transverse dual power source vehicle drive assembly coupled to a front or rear axle of a vehicle for driving a vehicle.

Background of the invention

In the current pure electric or hybrid new energy vehicles, the dynamic characteristics of the electric motor used are different from the requirements of the complete vehicle, and the speed ratio and torque requirements cannot be met. As new energy vehicles need to face more and more complicated working conditions, users have higher and higher requirements for the comfort and cruising range of new energy vehicles. Simple motor direct drive mode, motor connection reducer mode or hybrid electric power. The new energy vehicles of the model can no longer meet the development requirements of the new energy automobile industry.

In the current vehicle powertrain, the power source, the clutch, the gearbox or the speed reducer, and the drive shaft are usually arranged in a longitudinal direction, have a large length, and occupy a large space of the vehicle, and are not suitable for some small vehicles that require a compact structure.

In addition, in the pure electric or hybrid new energy vehicles, the reducer has a large impact on the rotor shaft of the motor (the rotor shaft is not integrated with the input shaft), and the conventional friction clutch cannot be used. The clutch used can only be hard. The connection method does not have a buffer function and cannot meet the requirements of new energy vehicles.

In the existing direct drive mode motor, the power system has no clutch function, the traditional inertia friction synchronizer cannot be used, the transmission cannot be shifted, and only a single speed ratio can be used; the start and stop of the whole vehicle can only be started by the motor. And stop, affecting the performance of the motor.

Summary of the invention

In view of the above problems in the prior art, the present invention provides a transverse dual power source vehicle drive assembly to solve the problem of the existing powertrain single speed ratio transmission, which cannot adapt to complicated road conditions.

At the same time, the existing powertrain has a large longitudinal dimension, cannot be used on a compact vehicle, and has a large number of gears in the transmission and a complicated transmission structure.

In order to achieve the above object, the technical solution of the present invention is implemented as follows:

The present invention provides a transverse dual power source vehicle drive assembly coupled to an axle half axle, the vehicle drive assembly including a first power source, a second power source, and an automatic transmission, the automatic transmission being provided with a first An input shaft and a second input shaft, wherein the power source is respectively connected to the two input shafts, and the automatic transmission and the axle half shaft connection are provided with a differential;

In the automatic transmission, a first intermediate shaft is disposed in parallel with the first input shaft, a second intermediate shaft is disposed coaxially with the first input shaft, and a third intermediate shaft is disposed coaxially with the first intermediate shaft. a first clutch is disposed between the first intermediate shaft and the third intermediate shaft, and a second clutch is disposed between the first input shaft and the second intermediate shaft;

a first gear is disposed on the first input shaft, a second gear is disposed on the first intermediate shaft, a first gear is meshed with the second gear, and a third gear is disposed on the second input shaft. a fourth gear is disposed on the second intermediate shaft, and the third gear is meshed with the fourth gear;

a fifth gear is further disposed on the second intermediate shaft, a sixth gear is disposed on the third intermediate shaft, a seventh gear is disposed on the differential, and the fifth gear and the sixth gear are meshed and transmitted. The six gears are simultaneously meshed with the seventh gear.

Further, the second power source is an electric motor, and when the first clutch and the second clutch are disconnected, the second power source sequentially passes through the second input shaft, the third gear, the fourth gear, and the second intermediate shaft The fifth gear, the sixth gear, the seventh gear, and the differential transmit power to the axle half shaft.

Further, when the first clutch is engaged and the second clutch is disconnected, the first power source sequentially passes through the first input shaft, the first gear, the second gear, the first intermediate shaft, the first clutch, and the third The intermediate shaft, the sixth gear, the seventh gear, and the differential transmit power to the axle half shaft.

Further, the first gear and the second gear meshing transmission ratio is i1, and the sixth gear and the seventh gear meshing gear ratio are i3. When the first clutch is engaged and the second clutch is disconnected, the automatic transmission is engaged. The gear ratio is i1×i3.

Further, when the second clutch is engaged and the first clutch is disconnected, the first power source sequentially passes through the first input shaft, the second clutch, the second intermediate shaft, the fifth gear, the sixth gear, and the seventh Gears and differentials transmit power to the axle axle.

Further, the fifth gear, the sixth gear and the seventh gear meshing transmission ratio are i2, and when the second clutch is engaged and the first clutch is disconnected, the meshing gear ratio of the automatic transmission is i2.

Further, the third gear and the fourth gear meshing transmission ratio is i4, the fifth gear, the sixth gear, and the seventh gear meshing gear ratio are i2, when the first clutch and the second clutch are disconnected, The second power source outputs power through an automatic transmission and at an engagement ratio of i4×i2.

Further, an eighth gear is further disposed on the third intermediate shaft;

The eighth gear meshes with a fifth gear on the second intermediate shaft, and the sixth gear is only meshed with the seventh gear.

Further, the first gear and the second gear meshing transmission ratio is i1, the sixth gear and the seventh gear meshing gear ratio are i3, the third gear and the fourth gear meshing gear ratio are i4, the fifth gear and the The eight gear meshing transmission ratio is i5;

When the first clutch is engaged and the second clutch is off, the meshing transmission ratio of the automatic transmission is i1×i3;

When the first clutch is disconnected and the second clutch is engaged, the meshing gear ratio of the automatic transmission is i5×i3;

When the first clutch and the second clutch are disconnected, the second power source outputs power through an automatic transmission at an meshing ratio of i4×i5×i3.

Further, the first power source is an electric motor, or an engine is combined with an ISG motor.

The present invention adopting the above configuration has the following advantages:

The vehicle powertrain of the invention is connected with the rear axle half shaft or the front axle half shaft of the vehicle, and the vehicle powertrain can realize dual power source input, three speed ratio transmission, flexible transmission mode and power input mode, and meets the whole vehicle. For the driving needs of different road conditions, when the vehicle is climbing on the load, the dual power input and the larger speed ratio transmission can be selected to improve the driving force of the whole vehicle and make up for the defects of insufficient driving force of the whole vehicle; when the whole vehicle is in the cruising state, Select single power input, smaller speed ratio transmission to meet the high-speed driving requirements of the whole vehicle, save energy and improve vehicle cruising range. In addition, when the vehicle starts, the first power source and the second power source are simultaneously activated, and the driving assembly can be increased. The total driving force enables the vehicle to shorten the acceleration process and achieve faster driving at higher speeds.

The design mode of the torsional vibration damper combined with the face gear clutch minimizes the kinetic energy loss, and compensates for the shortcoming of the conventional friction clutch due to the inability to withstand the power shock of the motor.

The transverse dual power source vehicle drive assembly provided by the invention shortens the longitudinal dimension of the drive assembly on the one hand, and is suitable for a compact vehicle; on the other hand, the transmission structure is simplified due to the small number of gears used.

BRIEF DESCRIPTION OF THE DRAWINGS

1 is a schematic structural view of a transverse dual power source vehicle drive assembly according to Embodiment 1 of the present invention;

2 is a schematic structural view of a transverse dual power source vehicle drive assembly according to Embodiment 2 of the present invention;

3 is a schematic structural view of a transverse dual power source vehicle drive assembly according to Embodiment 3 of the present invention.

In the figure: 10. automatic transmission; 11. first gear; 12. second gear; 13. third gear; 14. fourth gear; 15. fifth gear; 16. sixth gear; 18. The eighth gear;

21. a first input shaft; 22. a second input shaft;

31. a first intermediate shaft; 32. a second intermediate shaft; 33. a third intermediate shaft;

41. a first clutch; 42. a second clutch;

50. differential;

60. an electric motor;

70. engine; 71. ISG motor; 72. torsional vibration damper;

80. Axle.

Mode for carrying out the invention

The embodiments of the present invention will be further described in detail below with reference to the accompanying drawings.

Example 1

As shown in FIG. 1 , a first embodiment of the present invention provides a transverse dual power source vehicle drive assembly coupled to an axle half axle. The vehicle drive assembly includes a first power source, a second power source, and an automatic transmission 10 . The automatic transmission 10 is provided with a first input shaft 21 and a second input shaft 22, respectively, a first power source and a second power source An input shaft 21 and a second input shaft 22 are connected, and a differential 50 is disposed at the automatic transmission 10 and the axle half shaft connection.

In the automatic transmission 10, a first intermediate shaft 31 is disposed in parallel with the first input shaft 21, a second intermediate shaft 32 is disposed coaxially with the first input shaft 21, and a coaxial direction is provided with the first intermediate shaft 31. The third intermediate shaft 33.

A first clutch 41 is disposed between the first intermediate shaft 31 and the third intermediate shaft 33, and a second clutch 42 is disposed between the first input shaft 21 and the second intermediate shaft 32.

A first gear 11 is disposed on the first input shaft 21, and a second gear 12 is disposed on the first intermediate shaft 31. The first gear 11 is meshed with the second gear 12; the third input shaft 22 is provided with a third gear 13 The second intermediate shaft 32 is provided with a fourth gear 14 , and the third gear 13 is meshed with the fourth gear 14 ; the second intermediate shaft 32 is further provided with a fifth gear 15 , and the third intermediate shaft 33 is provided with a sixth gear The gear 16, the differential gear 50 is provided with a seventh gear 17, and the fifth gear 15 is meshed with the sixth gear 16, and the sixth gear 16 is simultaneously meshed with the seventh gear 17.

In the first embodiment, the first power source is the combination of the engine 70 and the ISG motor 71, on the one hand, the idle loss and pollution of the engine 70 can be reduced, and on the other hand, the ISG motor 71 functions as a generator, and can be regenerated and recovered. Energy to achieve energy savings. The second source of power is the electric motor 60. It can be seen from the above structure that the automatic transmission of the vehicle drive assembly of the first embodiment of the present invention is different from the layout mode of the input shaft, the intermediate shaft and the output shaft of the conventional transmission, and on the one hand, shortens the longitudinal dimension of the drive assembly, and is suitable for a compact structure. Vehicles; on the other hand, the number of gears used is small, simplifying the transmission process.

The power transmission mode of the above drive assembly is as follows:

When the first clutch 41 is engaged and the second clutch is off 42 , the first power source sequentially passes through the first input shaft 21 , the first gear 11 , the second gear 12 , the first intermediate shaft 31 , the first clutch 41 , and the first The three intermediate shafts 33, the sixth gear 16, the seventh gear 17, and the differential 50 transmit power to the axle half shaft.

The first gear 11 and the second gear 12 are set to have a gear ratio i1, and the sixth gear 16 and the seventh gear 17 are meshed with the transmission ratio i3. When the first clutch 41 is engaged and the second clutch 42 is disconnected, the automatic transmission is engaged. The gear ratio is i1×i3. This is the first condition.

When the second clutch 42 is engaged and the first clutch 41 is turned off, the first power source sequentially passes through the first input shaft 21, the second clutch 42, the second intermediate shaft 32, the fifth gear 15, the sixth gear 16, and the seventh Gear 17 and differential 50 transfer power to the axle axle.

The fifth gear 15, the sixth gear 16 and the seventh gear 17 are set to engage the gear ratio i2, the second clutch 42 is engaged, and the first clutch 41 is disconnected, the first power source passes through the automatic transmission, and the meshing ratio of the i2 is The power is output, and the sixth gear 16 is an idler. This is the second condition.

The second power source, that is, the electric motor 60 is used as the auxiliary power source. Since the electric motor can be arbitrarily adjusted, in the first working condition or the second working condition, if the electric motor 60 of the second power source is simultaneously activated, the driving force of the whole vehicle can be improved. The meshing gear ratio in the automatic transmission 10 still maintains the above results.

When the first clutch 41 and the second clutch 42 are disconnected, the second power source sequentially passes through the second input shaft 22, the third gear 13, the fourth gear 14, the second intermediate shaft 32, the fifth gear 15, and the sixth gear 16. The seventh gear 17 and the differential 50 transmit power to the axle axle.

The third gear 13 and the fourth gear 14 are set to mesh with the transmission ratio i4. When the first clutch 41 and the second clutch 42 are disengaged, the second power source passes through the automatic transmission to output power at an engagement ratio of i4×i2. This is the third condition.

When in the third operating condition, the engine 70 can serve as an auxiliary power source, and at this time, the first clutch 41 or the second clutch 42 is engaged to provide a larger driving force under the third working condition;

When the first clutch 41 and the second clutch 42 are disconnected, the first power source is activated, the power of the first power source cannot be transmitted to the axle half axle, and only the ISG motor 71 functions as a generator to regeneratively generate electricity. Stored in the battery or used for operation of the second power source.

Among them, the sizes of the gear ratios i1, i2, i3, and i4 can be changed by changing the size or the number of teeth of the gear, thereby changing the gear ratio of the automatic transmission 10. In the present embodiment, the diameter of the fourth gear 14 is smaller than that of the fifth gear 15.

It can be seen from the above that the drive assembly of the embodiment of the present invention can realize three transmission ratios:

The engine 70 of the first power source is activated, the first clutch 41 is engaged, and when the second clutch 42 is turned off, the meshing gear ratio in the automatic transmission 10 is i1 × i3. At this time, the second power source can be turned on or off. Second When the power source is started, the total driving force of the drive assembly can be increased, and when the vehicle starts, the vehicle can be shortened and the high-speed driving can be realized more quickly.

The engine 70 of the first power source is activated, the second clutch 42 is engaged, and when the first clutch 41 is off, the meshing gear ratio in the automatic transmission 10 is i2. At this time, the second power source can be turned on or off. Similarly, when the second power source is activated, the total driving force of the drive assembly can be increased.

The electric motor 60 of the second power source is activated, and when the first clutch 41 and the second clutch 42 are turned off, the meshing gear ratio in the automatic transmission 10 is i4 × i2. At this time, the engine 70 of the first power source can be turned on or off. When the first power source is started, the power of the first power source cannot be transmitted to the axle half axle, and only the ISG motor 71 functions as a generator, and the power can be regenerated, stored in the battery, or used for the second power source.

It can be seen from the above that the vehicle drive assembly can realize dual power source input and three speed ratio transmissions, and the transmission form is flexible, and can meet the driving demand of the vehicle for different road conditions. When the vehicle is climbing on a load, the double power input can be selected. Large speed ratio transmission, improve the driving force of the whole vehicle and make up for the defects of insufficient driving force of the whole vehicle; when the whole vehicle is in the cruising state, it can select single power input and small speed ratio transmission to meet the high speed driving requirements of the whole vehicle, saving Energy, improve vehicle cruising range. In addition, when the vehicle starts, the first power source and the second power source are simultaneously activated, which can increase the total driving force of the driving assembly, shorten the acceleration process of the vehicle, and realize high-speed driving more quickly.

In the embodiment of the present invention, the axle half shaft is the front axle half axle or the rear axle half axle; when the vehicle driving assembly is connected with the front axle half shaft, the vehicle is in the front drive mode, and the vehicle driving assembly is connected with the rear axle half shaft. The vehicle is in the rear drive mode.

The first clutch 41 and the second clutch 42 are end face clutches, including a movable toothed disc and a fixed toothed disc for engaging transmission, and the movable toothed disc is provided with end face transmission teeth or tooth grooves, and the fixed toothed disc is correspondingly provided with a face tooth groove. Or drive teeth. The face tooth clutch can minimize the kinetic energy loss with respect to the friction clutch, which makes up for the defect that the conventional friction clutch has a short life due to the inability to withstand the power shock of the motor.

The driving method of the face gear clutch can be electromagnetically driven (driven by electromagnet), hydraulically driven (driven by hydraulic mechanism), pneumatically driven (driven by pneumatic mechanism), or electrically driven (driven by electric motor) ), the movable movable toothed disk is axially moved to mesh with the fixed toothed disc.

When the first clutch 41 and the second clutch 42 are electromagnetic pinch clutches, when the vehicle drive assembly is in power input, the electromagnetic toothed clutch can disengage and combine the power and the vehicle at any time, thereby realizing the power. The smooth switching improves the smoothness of the vehicle.

Example 2

Embodiment 2 of the present invention is an improvement made on the basis of Embodiment 1. The difference between Embodiment 2 of the present invention and Embodiment 1 is that, as shown in FIG. 2, an eighth gear 18 is disposed on the third intermediate shaft 33, At this time, the fifth gear 15 and the eighth gear 18 mesh with the transmission; the sixth gear 16 is only meshed with the seventh gear 17.

The fifth gear 15 and the eighth gear 18 are set to have an engagement ratio of i5, and the sixth gear 16 and the seventh gear 17 are meshed with the transmission ratio i3. When the first clutch 41 is disconnected and the second clutch 42 is engaged, the first power is The source passes through the automatic transmission 10 to output power at an meshing ratio of i5 x i3.

The third gear 13 and the fourth gear 14 are set to mesh with the transmission ratio i4. When the first clutch 41 and the second clutch 42 are disconnected, the second power source passes through the automatic transmission 10 with an meshing ratio of i4×i5×i3. Output power.

The different gear ratio settings of this embodiment 2 are more flexible and less constrained. When the large gear ratio is selected, the diameter of the gear is smaller, and the radial size of the automatic transmission can be effectively reduced.

In the present embodiment, the diameter of the fourth gear 14 is larger than that of the fifth gear 15.

Other contents of Embodiment 2 of the present invention are the same as Embodiment 1, and the description thereof will not be repeated here.

Example 3

Embodiment 3 of the present invention is an improvement made on the basis of Embodiment 1. The difference between Embodiment 3 of the present invention and Embodiment 1 is that, as shown in FIG. 3, in Embodiment 3 of the present invention, the first power source is adopted. Motor 70.

Other contents of Embodiment 3 of the present invention are the same as Embodiment 1, and the description thereof will not be repeated here.

Example 4

In the fourth embodiment of the present invention, as shown in FIG. 1 or FIG. 2, a torsional vibration damper 72 is provided between the engine 70 and the ISG motor 71, and the torsional vibration damper 72 has a buffering function to reduce the engagement of the engine 70 with the ISG motor 71. Part of the torsional stiffness, which reduces the natural frequency of the torsional vibration and eliminates torsional vibration.

Other contents of Embodiment 4 of the present invention are the same as those of Embodiment 1, and the description thereof will not be repeated here.

The above is only a specific embodiment of the present invention, and other improvements or modifications may be made by those skilled in the art based on the above embodiments. It should be understood by those skilled in the art that the foregoing detailed description of the invention is intended to provide a better understanding of the scope of the invention.

Claims

A transverse dual power source vehicle drive assembly coupled to an axle axle, wherein the vehicle drive assembly includes a first power source, a second power source, and an automatic transmission, the automatic transmission being provided with a An input shaft and a second input shaft, wherein the power source is respectively connected to the two input shafts, and the automatic transmission and the axle half shaft connection are provided with a differential;

In the automatic transmission, a first intermediate shaft is disposed in parallel with the first input shaft, a second intermediate shaft is disposed coaxially with the first input shaft, and a third intermediate shaft is disposed coaxially with the first intermediate shaft. a first clutch is disposed between the first intermediate shaft and the third intermediate shaft, and a second clutch is disposed between the first input shaft and the second intermediate shaft;

a first gear is disposed on the first input shaft, a second gear is disposed on the first intermediate shaft, a first gear is meshed with the second gear, and a third gear is disposed on the second input shaft. a fourth gear is disposed on the second intermediate shaft, and the third gear is meshed with the fourth gear;

a fifth gear is further disposed on the second intermediate shaft, a sixth gear is disposed on the third intermediate shaft, a seventh gear is disposed on the differential, and the fifth gear and the sixth gear are meshed and transmitted. The six gears are simultaneously meshed with the seventh gear.
The vehicle drive assembly of claim 1 wherein said second source of power is an electric motor, said second source of power sequentially passing said second input when said first clutch and said second clutch are open The shaft, the third gear, the fourth gear, the second intermediate shaft, the fifth gear, the sixth gear, the seventh gear, and the differential transmit power to the axle half shaft.
The vehicle drive assembly according to claim 2, wherein when the first clutch is engaged and the second clutch is off, the first power source sequentially passes through the first input shaft, the first gear, and the first The two gears, the first intermediate shaft, the first clutch, the third intermediate shaft, the sixth gear, the seventh gear, and the differential transmit power to the axle half shaft.
The vehicle drive assembly according to claim 3, wherein said first gear and said second gear mesh ratio are i1, and said sixth gear and said seventh gear mesh ratio are i3, said first clutch When the second clutch is disconnected, the meshing gear ratio of the automatic transmission is i1×i3.
The vehicle drive assembly according to claim 2, wherein when the second clutch is engaged and the first clutch is disconnected, the first power source sequentially passes through the first input shaft, the second clutch, and the first The two intermediate shafts, the fifth gear, the sixth gear, the seventh gear, and the differential transmit power to the axle half shaft.
The vehicle drive assembly according to claim 5, wherein said fifth gear, said sixth gear and said seventh gear meshing transmission ratio are i2, said second clutch is engaged, and said first clutch is disengaged The meshing gear ratio in the automatic transmission is i2.
The vehicle drive assembly according to claim 2, wherein the third gear and the fourth gear meshing transmission ratio is i4, and the fifth gear, the sixth gear, and the seventh gear meshing gear ratio are i2, When the first clutch and the second clutch are disconnected, the second power source outputs power through an automatic transmission at an meshing ratio of i4×i2.
The vehicle drive assembly according to claim 1, wherein the third intermediate shaft is further provided with an eighth gear;

The eighth gear meshes with a fifth gear on the second intermediate shaft, and the sixth gear is only meshed with the seventh gear.
The vehicle drive assembly according to claim 8, wherein the first gear and the second gear meshing transmission ratio is i1, and the sixth gear and the seventh gear meshing gear ratio are i3, the third gear and the fourth gear. The gear meshing transmission ratio is i4, the fifth gear and the eighth gear meshing gear ratio is i5;

When the first clutch is engaged and the second clutch is off, the meshing transmission ratio of the automatic transmission is i1×i3;

When the first clutch is disconnected and the second clutch is engaged, the meshing gear ratio of the automatic transmission is i5×i3;

When the first clutch and the second clutch are disconnected, the second power source outputs power through an automatic transmission at an meshing ratio of i4×i5×i3.
The vehicle drive assembly of claim 1 wherein said first source of power is an electric motor or an engine is combined with an ISG motor.